# Probing dark matter structure down to $10^7$ solar masses: flux ratio   statistics in gravitational lenses with line of sight halos

**Authors:** Daniel Gilman, Simon Birrer, Tommaso Treu, Anna Nierenberg, Andrew, Benson

arXiv: 1901.11031 · 2019-07-30

## TL;DR

This paper extends a modeling framework to analyze flux ratios in gravitational lensing of quasars, providing new constraints on dark matter properties and demonstrating that about 50 quads can distinguish between warm and cold dark matter models.

## Contribution

It introduces an extended forward modeling approach incorporating line of sight halos, improving dark matter constraints from gravitational lensing data.

## Key findings

- Constraints on half-mode mass $m_{hm}$ vary with tidal destruction assumptions.
- Warm dark matter models are favored over cold dark matter with specific likelihood ratios.
- Approximately 50 quads are sufficient to differentiate dark matter types.

## Abstract

Strong lensing provides a powerful means of investigating the nature of dark matter as it probes dark matter structure on sub-galactic scales. We present an extension of a forward modeling framework that uses flux ratios from quadruply imaged quasars (quads) to measure the shape and amplitude of the halo mass function, including line of sight (LOS) halos and main deflector subhalos. We apply this machinery to 50 mock lenses --- roughly the number of known quads --- with warm dark matter (WDM) mass functions exhibiting free-streaming cutoffs parameterized by the half-mode mass $m_{\rm{hm}}$. Assuming cold dark matter (CDM), we forecast bounds on $m_{\rm{hm}}$ and the corresponding thermal relic particle masses over a range of tidal destruction severity, assuming a particular WDM mass function and mass-concentration relation. With significant tidal destruction, at $2 \sigma$ we constrain $m_{\rm{hm}}<10^{7.9} \left(10^{8.4}\right) M_{\odot}$, or a 4.4 (3.1) keV thermal relic, with image flux uncertainties from measurements and lens modeling of $2\% \left(6\%\right)$. With less severe tidal destruction we constrain $m_{\rm{hm}}<10^{7} \left(10^{7.4}\right) M_{\odot}$, or an 8.2 (6.2) keV thermal relic. If dark matter is warm, with $m_{\rm{hm}} = 10^{7.7} M_{\odot}$ (5.1 keV), we would favor WDM with $m_{\rm{hm}} > 10^{7.7} M_{\odot}$ over CDM with relative likelihoods of 22:1 and 8:1 with flux uncertainties of $2\%$ and $6\%$, respectively. These bounds improve over those obtained by modeling only main deflector subhalos because LOS objects produce additional flux perturbations, especially for high redshift systems. These results indicate that $\sim 50$ quads can conclusively differentiate between warm and cold dark matter.

## Full text

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## Figures

23 figures with captions in the complete paper: https://tomesphere.com/paper/1901.11031/full.md

## References

104 references — full list in the complete paper: https://tomesphere.com/paper/1901.11031/full.md

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Source: https://tomesphere.com/paper/1901.11031